The Invariant Set Postulate: a new geometric framework for the foundations of quantum theory and the role played by gravity

A new law of physics is proposed, defined on the cosmological scale but with significant implications for the microscale. Motivated by nonlinear dynamical systems theory and black-hole thermodynamics, the Invariant Set Postulate proposes that cosmological states of physical reality belong to a non-computable fractal state-space geometry I, invariant under the action of some subordinate deterministic causal dynamics DI. An exploratory analysis is made of a possible causal realistic framework for quantum physics based on key properties of I. For example, sparseness is used to relate generic counterfactual states to points p∉I of unreality, thus providing a geometric basis for the essential contextuality of quantum physics and the role of the abstract Hilbert Space in quantum theory. Also, self-similarity, described in a symbolic setting, provides a possible realistic perspective on the essential role of complex numbers and quaternions in quantum theory. A new interpretation is given to the standard ‘mysteries’ of quantum theory: superposition, measurement, non-locality, emergence of classicality and so on. It is proposed that heterogeneities in the fractal geometry of I are manifestations of the phenomenon of gravity. Since quantum theory is inherently blind to the existence of such state-space geometries, the analysis here suggests that attempts to formulate unified theories of physics within a conventional quantum-theoretic framework are misguided, and that a successful quantum theory of gravity should unify the causal non-Euclidean geometry of space–time with the atemporal fractal geometry of state space. The task is not to make sense of the quantum axioms by heaping more structure, more definitions, more science fiction imagery on top of them, but to throw them away wholesale and start afresh. We should be relentless in asking ourselves: From what deep physical principles might we derive this exquisite structure? These principles should be crisp, they should be compelling. They should stir the soul.Chris Fuchs (Gilder 2008, p. 335)

[1]  M. E. Naschie,et al.  A review of E infinity theory and the mass spectrum of high energy particle physics , 2004 .

[2]  D. Deutsch The fabric of reality , 1997, The Art of Political Storytelling.

[3]  Shinfield Park A Local Deterministic Model of Quantum Spin Measurement by , 1995 .

[4]  J. Butterfield The End of Time , 2001, gr-qc/0103055.

[5]  R. Penrose Gravitational collapse and spacetime singularities , 1965 .

[6]  H. Price Time's arrow and Archimedes' point new directions for the physics of time , 1997 .

[7]  Andrei Khrennikov,et al.  Non-Archimedean Analysis: Quantum Paradoxes, Dynamical Systems and Biological Models , 2011 .

[8]  E. Lorenz Deterministic nonperiodic flow , 1963 .

[9]  J. Barrow,et al.  Why is nature described by quantum theory , 2004 .

[10]  R. Penrose On Space and Time: Causality, quantum theory and cosmology , 2008 .

[11]  B. Hiley The Undivided Universe , 1993 .

[12]  Fractals and Symbolic Dynamics as Invariant Descriptors of Chaos inGeneral , .

[13]  M. Bojowald What happened before the Big Bang , 2007 .

[14]  Joan S. Birman,et al.  Knotted periodic orbits in dynamical systems—I: Lorenz's equation , 1983 .

[15]  Sergio Albeverio,et al.  A Regularization of Quantum Field Hamiltonians with the Aid of p–adic Numbers , 1998 .

[16]  F. Takens Detecting strange attractors in turbulence , 1981 .

[17]  Fractals and Symbolic Dynamics as Invariant Descriptors of Chaos in General Relativity , 1997, gr-qc/9709036.

[18]  Michel L. Lapidus,et al.  Fractal Geometry, Complex Dimensions and Zeta Functions , 2006 .

[19]  S.W.Hawking The Nature of Space and Time , 1994 .

[20]  L. Nottale,et al.  Fractals and nonstandard analysis , 1984 .

[21]  H. Stowell The emperor's new mind R. Penrose, Oxford University Press, New York (1989) 466 pp. $24.95 , 1990, Neuroscience.

[22]  Martin Ehrendorfer,et al.  Predictability of Weather and Climate: The Liouville equation and atmospheric predictability , 2006 .

[23]  G Ord,et al.  Fractal space-time: a geometric analogue of relativistic quantum mechanics , 1983 .

[24]  Gerard 't Hooft The mathematical basis for deterministic quantum mechanics , 2006 .

[25]  R. Penrose,et al.  Causality, quantum theory and cosmology , 2008 .

[26]  Gabriel B. Mindlin,et al.  TOPOLOGICAL STRUCTURE OF CHAOTIC FLOWS FROM HUMAN SPEECH DATA , 1999 .

[27]  H. Atmanspacher,et al.  Complementarity in Classical Dynamical Systems , 2006 .

[28]  Steven Weinstein Nonlocality Without Nonlocality , 2008, 0812.0349.

[29]  S. Hawking Black holes in general relativity , 1972 .

[30]  Elnaschie A REVIEW OF E INFINITY THEORY AND THE MASS SPECTRUM OF HIGH ENERGY PARTICLE PHYSICS , 2004 .

[31]  David D. Nolte,et al.  The Age of Entanglement , 2001 .

[32]  Douglas Lind,et al.  An Introduction to Symbolic Dynamics and Coding , 1995 .

[33]  T. Palmer A granular permutation-based representation of complex numbers and quaternions: elements of a possible realistic quantum theory , 2004, Proceedings of the Royal Society of London. Series A: Mathematical, Physical and Engineering Sciences.

[34]  Simant Dube Undecidable Problems in Fractal Geometry , 1993, Complex Syst..

[35]  Lenore Blum,et al.  Complexity and Real Computation , 1997, Springer New York.

[36]  S. Hawking Particle creation by black holes , 1975 .

[37]  E. T. An Introduction to the Theory of Numbers , 1946, Nature.

[38]  O. Rössler An equation for continuous chaos , 1976 .

[39]  Gerard 't Hooft,et al.  On the free-will postulate in Quantum Mechanics , 2007 .